If it aint broke dont fix it. It aint broke.
A primary problem is unaligned accesses. They go from bad to really bad depending on what architecture you are running on. A lot of it has to do with the programmers, some with the compilers.
The cheapest way to fix memcpy is to not use it, keep your data aligned on nice boundaries and use or make an alternate to memcpy that only supports nice aligned, block copies. Even better would be to have a compiler switch to sacrifice program space and ram for the sake of speed. folks or languages that use a lot of structures such that the compiler internally generates calls to memcpy or whatever that language equivalent is would have their structures grow such that there is a pad between or padding inside. A 59 byte structure may become 64 bytes instead. malloc or an alternative that only gives pointers to an address aligned as specified. etc etc.
It is considerably easier to just do all of this yourself. An aligned malloc, structures that are multiples of the alignement size. Your own memcpy that is aligned, etc. with it being that easy why would the hardware folks mess up their designs and compilers and users? there is no business case for it.
Another reason is that caches have changed the picture. your dram is only accessible in a fixed size, 32 bits 64 bits, something like that, any direct accesses smaller than that are a huge performance hit. Put the cache in front of that the performance hit goes way down, any read-modify-write happens in the cache with the modify allowing for mulitple modifies for a single read and write of dram. You still want to reduce the number of memory cycles to the cache, yes, and you can still see the performance gain by smoothing that out with the gear shift thing (8 bit first gear, 16 bit second gear, 32 bit third gear, 64 bit cruising speed, 32 bit shift down, 16 bit shift down, 8 bit shift down)
I cant speak for intel but do know that folks like ARM have done what you are asking a
for example is still four 32 bit transfers if the core uses a 32 bit interface. but for 64 bit interfaces if aligned on a 64 bit boundry it becomes a 64 bit transfer with a length of two, one set of negotiations between the parties and two 64 bit words move. If not aligned on a 64 bit boundary then it becomes three transfers a single 32 bit, a single 64 bit then a single 32 bit. You have to be careful, if these are hardware registers that may not work depending on the design of the register logic, if it only supports single 32 bit transfers you cant use that instruction against that address space. No clue why you would try something like that anyway.
The last comment is...it hurts when I do this...well dont do that. Dont single step into memory copies. the corollary to that is there is no way anyone would modify the design of the hardware to make single stepping a memory copy easier on the user, that use case is so small it doesnt exist. Take all the computers using that processor running at full speed day and night, measured against all the computers being single stepped through mem copies and other performance optimized code. It is like comparing a grain of sand to the width of the earth. If you are single stepping, you are still going to have to single step through whatever the new solution is if there were one. to avoid huge interrupt latencies the hand tuned memcpy will still start with an if-then-else (if too small of a copy just go into a small set of unrolled code or a byte copy loop) then go into a series of block copies at some optimal speed without horrible latency size. You will still have to single step through that.
to do single stepping debugging you have to compile screwed up, slow, code anyway, the easiest way to solve a single step through memcpy problem, is to have the compiler and linker when told to build for debug, build for and link against a non-optimized memcpy or an alternate non-optimized library in general. gnu/gcc and llvm are open source, you can make them do whatever you want.